#=======================================================================================
# RWX access on U-mode pages in S-mode with s/mstatus.SUM set for Level 0 PTE
#---------------------------------------------------------------------------------------
# Test Description:
#
# If PTE belongs to user mode i.e. its U permission bit is set (pte.u = 1)
# and m/sstatus.SUM = 1, then RW access to that PTE in supervisor mode would 
# be successful but eXecute access would raise instruction page fault exception
# in s-mode.
# 
# When satp.mode=sv32, PTE has (r,w,x) PMP permissions, PTE has non-reserved RWX
# encoding, and pte.v=1, then test the following in supervisor mode for level0 PTE.
# 
# - Set pte.r=1 & pte.u=1 & s/mstatus.SUM = 1 and test the read acces.
# - Set pte.w=1 & pte.u=1 & s/mstatus.SUM = 1 and test the write access.
# - Set pte.x=1 & pte.u=1 & s/mstatus.SUM = 1 and test the execute access.
#
#=======================================================================================

#include "macros.h"

#define _MMODE_ "M"
#define _SUMODE_ "SU"

.text
.global _start
.option norvc

_start:
    ALL_MEM_PMP                                                             # PMP permission to all the mem
    la t1,trap_handler                                                      # loads the address of trap handler 
    csrw mtvec,t1                                                           # sets the mtvec to trap handler
    
PTE_LEVEL1_SUPERVISOR:

# ----------------LEVEL 1 PTE Setup for load and store test---------------------

    la a1,pgtb_l0                                                           # loads the address of label pgtb_l0
    mv a0, a1                                                               # VA = PA - Identity Map
    ori a2, x0, ( PTE_V )                                                   # sets the permission bits
    PTE_SETUP_RV32(a1, a2, t1, a0, pgtb_l1, LEVEL1)                         # setup the PTE for level1

    la a1,vm_en                                                             # loads the address of label vm_en
    mv a0, a1                                                               # VA = PA - Identity Map
    ori a2, x0, ( PTE_D | PTE_A | PTE_X | PTE_V )                           # sets the permission bits
    PTE_SETUP_RV32(a1, a2, t1, a0, pgtb_l0, LEVEL0)                         # setup the PTE for level0
  
    la a1,rvtest_data                                                       # loads the address of label rvtest_data
    mv a0, a1                                                               # VA = PA - Identity Map
    ori a2, x0, ( PTE_D | PTE_A | PTE_U | PTE_W | PTE_R | PTE_V )           # sets the permission bits
    PTE_SETUP_RV32(a1, a2, t1, a0, pgtb_l0, LEVEL0)                         # setup the PTE for level0   

    la a1,rvtest_check                                                      # loads the address of label rvtest_data
    mv a0, a1                                                               # VA = PA - Identity Map                                         
    ori a2, x0, ( PTE_D | PTE_A | PTE_W | PTE_R | PTE_V)                    # sets the permission bits
    PTE_SETUP_RV32(a1, a2, t1, a0, pgtb_l0, LEVEL0)                         # setup the PTE for level0

# ----------------Set the SATP and change the mode---------------------


    SATP_SETUP_SV32(pgtb_l1)                                                # set the SATP for virtualization
    li a1, MSTATUS_SUM
    csrs mstatus, a1                                                        # Clear mstatus.SUM
    la a1,vm_en                                                             # loads the address of vm_en
    CHANGE_T0_S_MODE(a1)                                                    # changes mode M to S and set the MEPC value to a1

# ----------------Virtualization Enabeled---------------------

vm_en:

    la a1, rvtest_data                                                      # loads the address of label rvtest_data

check_store:

    sw t1,0(a1)                                                             # test the store access    

check_load:

    lw t1,0(a1)                                                             # tests the load access 
    SMODE_ECALL                                                             # SMODE ecall 
      
# ----------------------Execute test prolog------------------------------

    TEST_PROLOG(check_execute, CAUSE_FETCH_PAGE_FAULT)                      # load the addr and expected cause

# -------------LEVEL 0 PTE Setup for execute test------------------------
                                                                            # Setup a new PTE to test execute 
    la a1,check_execute                                                     # loads the address of label vm_en
    mv a0, a1                                                               # VA = PA - Identity Map
    ori a2, x0, ( PTE_D | PTE_A | PTE_U | PTE_X | PTE_V )                   # sets the permission bits
    PTE_SETUP_RV32(a1, a2, t1, a0, pgtb_l0, LEVEL0)                         # setup the PTE for level1

# ----------------Set the SATP and change the mode---------------------

    SATP_SETUP_SV32(pgtb_l1)                                                # set the SATP for virtualization
    la a1,check_execute                                                     # loads the address of check_execute
    CHANGE_T0_S_MODE(a1)                                                    # changes mode M to S and set the MEPC 

check_execute:    
                                                                            # test the execute access
    li t1, 0x45                                                             # page fault should raise 
    TEST_STATUS                                                             # checks the status of the test
    j test_pass

trap_handler:

    csrr t0, mcause                                                         # read the value of mcause 
    la t1, rvtest_check                                                     # load the address of trvtest_check
    
    lw t2, 0(t1)                                                            # if cause expected then load 1 else 0
    lw t3, 4(t1)                                                            # load the expected value of mepc 
    lw t4, 8(t1)                                                            # load the expected value of mcause  

    li  t1, CAUSE_SUPERVISOR_ECALL                                          # load the value of supervisor ecall
    beq t0,t1,continue_in_m_mode                                            # checks if ecall is occured

    beqz t2, test_fail                                                      # Jumps to exit if cause is not expected
 
    csrr t5,mepc                                                            # read the value of mepc 
    bne t3,t5,test_fail                                                     # check the value of mepc with it's expected value
    
    bne  t0, t4, test_fail                                                  # jumps to exit if EXPECTED_CAUSE is'nt equal to mcause

    li t5, CAUSE_FETCH_PAGE_FAULT                                           # load the value of fetch page fault exception
    beq t0,t5,continue_in_m_mode                                            # if fetch page fault jump to next instr in M mode
    
continue_execution:

    INCREMENT_MEPC   _SUMODE_                                               # update the value of mepc
    j trap_epilogs

continue_in_m_mode:

    INCREMENT_MEPC   _MMODE_                                                # update the value of mepc
    li t1,MSTATUS_MPP                                                       # update the MPP to MSTATUS_MPP for M mode
    csrs mstatus,t1                                                         # update the value mstatus MPP

trap_epilogs:

    la t1, rvtest_check                                                     # load the addr of rvtest_check
    li t2, 0
    sw t2, 0(t1)                                                            # Clear the expected cause
    sw t2, 4(t1)                                                            # Clear the exception PC
    sw t2, 8(t1)                                                            # Clear cause execution number
    mret

test_pass:

    li x1, 0                                                                # Write 0 in x1 if test pass
    j exit                                                                  # Jump to exit

test_fail:

    li x1, 1                                                                # Write 1 in x1 if test failed

COREV_VERIF_EXIT_LOGIC                                                      # exit logic 

.data  
    rvtest_check: 

        .word 0xdeadbeef                                                    # 1 for cause expected 0  for no cause 
        .word 0xbeefdead                                                    # write the value of mepc here (where  cause is expected)
        .word 0xcafecafe                                                    # write the value of expect cause 
.align 12                                     
    rvtest_data:   
        .word 0xbeefcafe                                                 
        .word 0xdeadcafe                                                 
        .word 0xcafecafe                                                 
        .word 0xbeefdead  
.align 12                                                      
    pgtb_l1:                                                       
        .zero 4096                                                 
    pgtb_l0:                                                       
        .zero 4096                                                                                                     

.align 4; .global tohost;   tohost:   .dword 0;
.align 4; .global fromhost; fromhost: .dword 0;